Robots comprising projectors for projecting images on identified projection surfaces

ABSTRACT

Robots including projectors for projecting images on identified projection surfaces are disclosed. A robot includes a housing, an electronic control unit coupled to the housing, a projector coupled to the housing, a human recognition module coupled to the housing, and a projection surface identification module coupled to the housing. The projector, the human recognition module, and the surface identification module are communicatively coupled with the electronic control unit. The electronic control unit includes a non-transitory memory that stores a set of machine readable instructions and a processor for executing the machine readable instructions. When executed by the processor, the machine readable instructions cause the robot to recognize a human using the human recognition module, identify a projection surface using the projection surface recognition module, and project an image on the identified projection surface with the projector.

TECHNICAL FIELD

The present specification generally relates to robots and, morespecifically, robots comprising projectors for projecting images onidentified projection surfaces.

BACKGROUND

Robots, such as telepresence robots, may communicate image data to ahuman in the physical environment of the robot (e.g., image data of aremote party communicating via a telepresence robot to a party in thephysical presence of the telepresence robot) by displaying the imagedata on a monitor, television, screen, display, or the like, forexample. However, in the case where the image data is projected, it maybe difficult to identify an appropriate surface on which to project theimage data so that one or more humans communicating with the robot mayeasily view the projected image. For example, projection surfaces may besmall, obstructed by objections, or behind one or more people in thephysical environment.

Accordingly, a need exists for alternative robots comprising projectorsfor projecting images on identified projection surfaces.

SUMMARY

In one embodiment, a robot includes a housing, an electronic controlunit coupled to the housing, a projector coupled to the housing, a humanrecognition module coupled to the housing, and a projection surfaceidentification module coupled to the housing. The projector, the humanrecognition module, and the surface identification module arecommunicatively coupled with the electronic control unit. The electroniccontrol unit includes a non-transitory memory that stores a set ofmachine readable instructions and a processor for executing the machinereadable instructions. When executed by the processor, the machinereadable instructions cause the robot to recognize a human using thehuman recognition module, identify a projection surface using theprojection surface recognition module, and project an image on theidentified projection surface with the projector.

In another embodiment, a robot includes a housing, an electronic controlunit coupled to the housing, a projector coupled to the housing, and acamera coupled to the housing. The projector and the camera arecommunicatively coupled with the electronic control unit. The electroniccontrol unit comprises a non-transitory memory that stores a set ofmachine readable instructions and a processor for executing the machinereadable instructions. When executed by the processor, the machinereadable instructions cause the robot to recognize a human using thecamera, identify a projection surface using the camera, and project animage on the identified projection surface with the projector.

In yet another embodiment, a robot includes a housing, an electroniccontrol unit coupled to the housing, a projector coupled to the housing,a microphone coupled to the housing, and a camera coupled to thehousing. The projector, the microphone, and the camera arecommunicatively coupled to the electronic control unit. The electroniccontrol unit includes a non-transitory memory that stores a set ofmachine readable instructions and a processor for executing the machinereadable instructions. When executed by the processor, the machinereadable instructions cause the robot to recognize a human based on amechanical vibration received by the microphone and transforming themechanical vibration into a signal indicative of human speech that istransmitted to the electronic control unit, identify a projectionsurface using the camera, and project an image on the identifiedprojection surface.

These and additional features provided by the embodiments describedherein will be more fully understood in view of the following detaileddescription, in conjunction with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The embodiments set forth in the drawings are illustrative and exemplaryin nature and not intended to limit the subject matter defined by theclaims. The following detailed description of the illustrativeembodiments can be understood when read in conjunction with thefollowing drawings, where like structure is indicated with likereference numerals and in which:

FIG. 1 schematically depicts a robot for projecting images on identifiedsurfaces, according to one or more embodiments shown and describedherein;

FIG. 2 schematically depicts a robot for projecting images on identifiedsurfaces, according to one or more embodiments shown and describedherein;

FIG. 3 schematically depicts a flowchart for projecting an image on anidentified projection surface viewable by a human, according to one ormore embodiments shown and described herein;

FIG. 4 schematically depicts a flowchart for moving a robot to projectan image on an identified projection surface viewable by a human,according to one or more embodiments shown and described herein;

FIG. 5 schematically depicts a perspective view of a wheeled robotprojecting an image on a surface viewable by a human, according to oneor more embodiments shown and described herein; and

FIG. 6 schematically depicts a perspective view of a flying robotprojecting an image on a surface viewable by a human, according to oneor more embodiments shown and described herein.

DETAILED DESCRIPTION

The embodiments disclosed herein generally include robots comprisingprojectors for projecting images on identified surfaces. Referringgenerally to FIG. 5, a robot may recognize a human in the physicalenvironment of the robot, identify a projection surface viewable by thehuman onto which an image may be projected, and project an image on theidentified surface, such as an image of a human, a face, an avatarrepresentative of the robot, or the like. More specifically, embodimentsgenerally include a housing, an electronic control unit coupled to thehousing, and a projector coupled to the housing and communicativelycoupled with the housing. Embodiments generally recognize a human,identify a projection surface, and project an image on the identifiedprojection surface with the projector. Some embodiments include a humanrecognition module coupled to the housing and communicatively coupledwith the electronic control unit for recognizing the human, and aprojection surface identification module coupled to the housing andcommunicatively coupled with the electronic control unit for identifyingthe projection surface. Other embodiments include a camera coupled tothe housing and communicatively coupled with the electronic control unitfor recognizing the human and identifying the projection surface. Stillother embodiments include a microphone coupled to the housing andcommunicatively coupled with the electronic control unit for recognizingthe human and a camera coupled to the housing and communicativelycoupled with the electronic control unit for identifying the projectionsurface. The various robots for projecting images on identified surfaceswill be described in more detail herein with specific reference to thecorresponding drawings.

Referring now to the drawings, FIG. 1 schematically depicts anembodiment of a robot 100 for projecting images on identified surfaces.The robot 100 comprises a housing 102 to which the various components ofthe robot 100 are coupled. The robot 100 depicted in FIG. 1 includes aplurality of drive wheels 114 rotatably coupled to the housing 102operable to move the robot 100. However, it should be understood that inother embodiments, the robot 100 may be configured to move in a mannerother than utilizing wheels. For example, the robot 100 may be any othertype of robot including, but not limited to, a robot with drive tracks,a robot with legs, an aquatic robot, and a flying robot (e.g., anairplane robot, a helicopter robot, a blimp robot, etc.). It should alsobe understood that in some embodiments, the housing 102 may enclose someor all of the components of the robot 100. In other embodiments, atleast some of the components of the robot 100 may be coupled to anoutside surface of the housing 102.

The housing 102 includes an electronic control unit 120 coupled to thehousing 102. The electronic control unit 120 includes an electronicmemory 122 that stores a set of machine readable instructions and aprocessor 124 for executing machine readable instructions. Theelectronic memory 122 may comprise RAM, ROM, flash memories, harddrives, or any device capable of storing machine readable instructionssuch that the machine readable instructions can be accessed by theprocessor 124. The machine readable instructions comprise logic oralgorithm(s) written in any programming language of any generation(e.g., 1GL, 2GL, 3GL, 4GL, or 5GL) such as, for example, machinelanguage that may be directly executed by the processor 124, or assemblylanguage, object-oriented programming (OOP), scripting languages,microcode, etc., that may be compiled or assembled into machine readableinstructions and stored in the electronic memory 122. Alternatively, themachine readable instructions may be written in a hardware descriptionlanguage (HDL), such as logic implemented via either afield-programmable gate array (FPGA) configuration or anapplication-specific integrated circuit (ASIC), or their equivalents.Accordingly, the methods described herein may be implemented in anyconventional computer programming language, as pre-programmed hardwareelements, or as a combination of hardware and software components. Theelectronic memory 122 may be implemented as one memory module or aplurality of memory modules.

The processor 124 may be any device capable of executing machinereadable instructions. For example, the processor 124 may be anintegrated circuit, a microchip, a computer, or any other computingdevice. The electronic memory 122 and the processor 124 are coupled to acommunication path 104 that provides signal interconnectivity betweenvarious components and/or modules of the robot 100. Accordingly, thecommunication path 104 may communicatively couple any number ofprocessors with one another, and allow the modules coupled to thecommunication path 104 to operate in a distributed computingenvironment. Specifically, each of the modules may operate as a nodethat may send and/or receive data. As used herein, the term“communicatively coupled” means that coupled components are capable ofexchanging data signals with one another such as, for example,electrical signals via conductive medium, electromagnetic signals viaair, optical signals via optical waveguides, and the like.

Accordingly, the communication path 104 may be formed from any mediumthat is capable of transmitting a signal such as, for example,conductive wires, conductive traces, optical waveguides, or the like.Moreover, the communication path 104 may be formed from a combination ofmediums capable of transmitting signals. In some embodiments, thecommunication path 104 comprises a combination of conductive traces,conductive wires, connectors, and buses that cooperate to permit thetransmission of electrical data signals to components such asprocessors, memories, sensors, input devices, output devices, andcommunication devices. Additionally, it is noted that the term “signal”means a waveform (e.g., electrical, optical, magnetic, mechanical orelectromagnetic), such as DC, AC, sinusoidal-wave, triangular-wave,square-wave, vibration, and the like, capable of traveling through amedium.

In the embodiments described herein, the electronic memory 122 and theprocessor 124 are integral with the electronic control unit 120.However, it is noted that the electronic control unit 120, theelectronic memory 122, and the processor 124 may be discrete componentscommunicatively coupled to one another without departing from the scopeof the present disclosure.

As schematically depicted in FIG. 1, the communication path 104communicatively couples the electronic control unit 120 with a pluralityof other components of the robot 100. For example, the embodiment of therobot 100 depicted in FIG. 1 includes an electronic control unit 120communicatively coupled to: a projector 126, a human recognition module128, a projection surface identification module 130, a wirelesscommunicator 132, a speaker 134, a plurality of drive motors 140 coupledto the plurality of drive wheels 114, and a steering mechanism 150coupled to at least one of the drive wheels 114.

The projector 126 may be any device capable of transforming a datasignal into an optical output, such as an image to be projected on asurface. In some embodiments, the projector 126 may include one or moreprocessors and one or more memories. In other embodiments, the projector126 may omit a processor and/or a memory. In some embodiment, theprojector 126 may be a compact, low-power projector, such as a picoprojector.

The human recognition module 128 may be any device capable offacilitating the identification of a human in the physical presence ofthe robot 100. In some embodiments, as will be explained more fullybelow, the human recognition module 128 may also identify a location ofone or more people, which may be used to determine an appropriateprojection surface. In other embodiments, the human recognition module128 is a camera communicatively coupled to the electronic control unit120. In such embodiments, the electronic control unit 120 may recognizea human in the physical presence of the robot 100 by employing facialrecognition algorithms on images detected by the camera. In otherembodiments, the human recognition module 128 is a microphonecommunicatively coupled to the electronic control unit 120. In suchembodiments, the electronic control unit 120 may recognize a human inthe physical presence of the robot 100 by receiving a mechanicalvibration at the microphone and transforming the received mechanicalvibration into a signal indicative of human speech. In some embodiments,as will be explained more fully below, the location and/or orientationof the human may be determined based on a direction of the receivedmechanical vibration. It should be understood that in other embodiments,the human recognition module 128 may be a device other than a camera ora microphone that facilitates the recognition of a human, such as anobject sensor, a heat sensor, a pressure sensor, a carbon dioxidesensor, etc.

The projection surface identification module 130 may be any devicecapable of facilitating the identification of an appropriate projectionsurface for the robot 100 to project an image with the projector 126. Insome embodiments, the projection surface identification module 130 is acamera communicatively coupled to the electronic control unit 120. Insuch an embodiment, the electronic control unit 120 may recognize a oneor more possible projection surfaces by processing an image detected bythe camera. From the one or more possible projection surfaces, theelectronic control unit 120 may identify a projection surface onto whichto project an image. In other embodiments, the projection surfaceidentification module 130 may be a device other than a camera thatfacilitates the identification of a projection surface, such as a depthsensor, an object sensor, a laser sensor, etc. In some embodiments, theprojection surface identification module 130 may make reference to aknown map stored in the electronic memory 122. In some embodiments, theprojection surface identification module 130 may facilitate theidentification of a plurality of potential projection surfaces andidentify a best projection surface of the plurality of potentialprojection surfaces based on one or more determined characteristics ofeach potential projection surface (e.g., surface color, texture,reflectivity, size, shape, etc.).

The wireless communicator 132 may be any device capable of wirelesscommunication. The wireless communicator 132 may include a communicationtransceiver for sending and/or receiving data according to any wirelesscommunication standard. For example, the network interface hardware 118may include a chipset (e.g., antenna, processors, machine readableinstructions, etc.) to communicate with another device (e.g., a computeror a mobile device), over wireless computer networks such as, forexample, a personal area network, a local area network, a wide areanetwork, a cellular network, wireless fidelity (Wi-Fi), WiMax,Bluetooth, IrDA, Wireless USB, Z-Wave, ZigBee, or the like. Someembodiments of the robot 100 may not include the wireless communicator132.

The speaker 134 may be any device capable of transforming data signalstransmitted on the communication path 104 into mechanical vibrations,such as in order to provide an audible indication of informationcommunicated from the robot 100 to a human in the physical presence ofthe robot 100. Some embodiments of the robot 100 may not include thespeaker 134.

As shown in FIG. 1, the robot 100 comprises a movement mechanismcomprising one or more drive wheels 114 and one or more drive motors140. The drive wheel 114 is rotatably coupled to the housing 102. Thedrive motor 140 is coupled to the drive wheel 114 such that the drivemotor 140 rotates the drive wheel 114 to move the robot 100. In someembodiments, the drive motor 140 is a battery powered electric motorthat provides rotational energy to the drive wheel. In otherembodiments, a single drive motor 140 may rotate multiple wheels topropel the device. While the embodiment depicted in FIG. 1 includes aplurality of drive wheels 114, each of which is coupled to a drive motor140, in other embodiments, one or more of the drive wheels 114 may notbe coupled to a separate drive motor 140, such as when one drive motor140 drives multiple drive wheels 114. In still other embodiments, one ormore of the drive wheels 114 may not be coupled to a drive motor 140,such as in an embodiment in which drive wheels 114 located in a front ofthe robot 100 are coupled to a drive motor 140, but wheels located in arear of the robot 100 are not coupled to a drive motor 140.

The robot 100 comprises a steering mechanism 150 coupled to the housing102. The steering mechanism 150 directs the course of the robot 100 asthe robot 100 moves. The steering mechanism may be a mechanical linkagefor turning one or more of the drive wheels 114, a rack and pinion, arecirculating ball mechanism, an omni wheel, a mecanum wheel, or anyother device suitable for directing the course of the robot 100 as therobot 100 moves.

While the robot 100 depicted in FIG. 1 includes a wheeled movementmechanism, in other embodiments, the robot 100 may include a movementmechanism other than a wheeled movement mechanism. For example, in someembodiments, the robot 100 may include a helicopter movement mechanism,which may include one or more rotors 320 coupled to one or more drivemotors, as depicted in FIG. 4.

Referring now to FIG. 2, another embodiment of a robot 200 forprojecting images on identified surfaces is schematically depicted. Therobot 200 depicted in FIG. 2 differs from the robot 100 depicted in FIG.1 because the robot 200 of FIG. 2 includes a camera 160 communicativelycoupled to the electronic control unit 120, in place of the humanrecognition module 128 and the projection surface identification module130 of the robot 100 of FIG. 1. In the embodiment of FIG. 2, the camera160 of the robot 200 facilitates both the recognition of a human in thephysical presence of the robot 200 and the identification of anappropriate projection surface for the robot 200 to project an imagewith the projector 126. The camera 160 may facilitate the recognition ofa human in the physical presence of the robot 200 by employing facialrecognition algorithms on images detected by the camera 160, forexample. The camera 160 may facilitate the identification of anappropriate projection surface based on an image received from thecamera 160. The other depicted components of the robot 200 aresubstantially similar to the like numbered components of the robot 100,described above with reference to FIG. 1

Referring now to FIG. 3, a flowchart for projecting an image on anidentified projection surface viewable by a human is schematicallydepicted. Machine readable instructions for recognizing a human (block302), identifying a projection surface (block 304), and projecting animage (block 306) are stored in the electronic memory 122. In anembodiment comprising a human recognition module (such as the robot 100of FIG. 1), when executed by the processor 124, the machine readableinstructions for recognizing a human cause the robot to recognize ahuman using the human recognition module 128 in block 302. In anembodiment in which the human recognition module 128 comprises a cameraor an embodiment lacking the human recognition module 128 and includinga camera 160 (such as the robot 200 of FIG. 2), the machine readableinstructions of block 302 may cause the robot to recognize the human byreceiving an input image from the camera and processing the input imageusing facial recognition algorithms to recognize a human. In someembodiments, the Eigenfaces facial recognition algorithm may be employedto recognize the human. In other embodiments, a facial recognitionalgorithm other than the Eigenfaces algorithm may be used, such asprincipal component analysis algorithm, an independent componentanalysis algorithm, a linear discriminate analysis algorithm, etc. In anembodiment in which the human recognition module 128 comprises amicrophone, the machine readable instructions may cause the robot torecognize the human by processing a signal received from the microphoneusing a voice recognition algorithm, such as a universal backgroundmodel based algorithm or a joint factor analysis based algorithm.

Still referring to FIG. 3, in an embodiment comprising a projectionsurface identification module 130 (such as the robot 100 of FIG. 1),when executed by the processor 124, the machine readable instructionsfor identifying a projection surface cause the robot to identify aprojection surface using the projection surface identification module130 in block 304. In an embodiment in which the projection surfaceidentification module 130 comprises a camera or an embodiment lackingthe projection surface identification module 130 and including a camera160 (such as the robot 200 of FIG. 2), the machine readable instructionsmay cause the robot to identify a projection surface by receiving aninput image from the camera and processing the input image usingprojection surface identification algorithms. The projection surfaceidentification algorithms may identify the projection surface based onsurface color, texture, reflectivity, size, shape, etc. In someembodiments, the machine readable instructions may cause the robot toidentify a plurality of potential projection surfaces and identify abest projection surface of the plurality of potential projectionsurfaces based on one or more determined characteristics of eachpotential projection surface (e.g., surface color, texture,reflectivity, size, shape, etc.). The identified surface may be anysurface on which an image may be projected including, but not limitedto, a wall, a window, a cubicle, a screen, etc.

When executed by the processor 124, the machine readable instructionsfor projecting an image cause the robot to project an image on theidentified projection surface in block 306. In some embodiments, theprojected image may be of a remote communicating party utilizing therobot 100 to communicate with a receiving party located in the physicalenvironment of the robot 100. In some embodiments, the projected imagemay include the entire body of the communicating party. In otherembodiments, the projected image may include only a portion of the bodyof the communicating party, such as the face of the communicating party.In still other embodiments, the projected image may include a fictionalrepresentation of the communicating party, e.g., an avatar or the like.In other embodiments, the projected image may be any other visualinformation conveyed by the robot 100 for viewing by a human located inthe physical environment of the robot 100. In still other embodiments,the projected image may be a visual representation of the robot 100,such as an avatar, for example.

Referring now to FIG. 4, a flowchart for moving a robot to project animage on an identified projection surface viewable by a human isschematically depicted. Machine readable instructions for identifying alocation of the human (block 402), identifying a projection area of theprojection surface on which the human is capable of viewing the image(block 404), and causing the robot to move to a position in which theimage is projected in the identified projection area (block 406) arestored in the electronic memory 122. In an embodiment comprising a humanrecognition module 128 (such as the robot 100 of FIG. 1), when executedby the processor, the machine readable instructions for identifying alocation of the human may use the human recognition module 128 toidentify the location of the human in block 402. In an embodiment inwhich the human recognition module 128 comprises a camera or anembodiment lacking the human recognition module 128 and including acamera 160 (such as the robot 200 of FIG. 2), the machine readableinstructions may cause the robot to receive an input image from thecamera and process the input image to determine a location of the humanrelative to a grid system or coordinate system stored in the electronicmemory 122. In some embodiments, the grid system or coordinate system isdefined relative to map data including information pertaining to thephysical environment in which the robot is present. In some embodiments,an orientation of an identified human may be identified in addition toidentifying a location of the human by, for example, determining adirection in which the human's eyes are directed by analyzing image datareceived from the camera.

In an embodiment in which the human recognition module 128 comprises amicrophone, the machine readable instructions of block 402 may cause therobot to receive a mechanical vibration and provide a signal indicativeof human speech to the electronic control unit 120, which may determinea location and/or orientation of the human based on the received speechsignal.

When executed by the processor, the machine readable instructions maycause the robot to identify a projection area of the projection surfaceon which the human is capable of viewing the image in block 404. In anembodiment comprising a projection surface identification module 130(such as the robot 100 of FIG. 1), when executed by the processor 124,the machine readable instructions of block 404 cause the robot toidentify the projection area on which the human is capable of viewingthe image using the projection surface identification module 130. In anembodiment in which the projection surface identification module 130comprises a camera or an embodiment lacking the projection surfaceidentification module 130 and including a camera 160 (such as the robot200 of FIG. 2), the machine readable instructions may cause the robot toidentify the projection area by receiving an input image from the cameraand processing the input image using a projection area identificationalgorithm. In some embodiments, the projection area identificationalgorithm may identify the projection area based on the location of thehuman and/or the orientation of the human such that the human is capableof viewing the image from the human's detected location and orientation.

When executed by the processor, the machine readable instructions maycause the robot to move to a position in which the image is projected inthe identified projection area in block 406. Once the desired projectionarea is identified in block 404, the movement mechanism of the robot maycause the robot to move to a position in which the image is projected inthe identified projection area by, in the case of a wheeled robot,rolling and steering to the appropriate location. In some embodiments,the robot may utilize any number of sonar sensors, laser range finders,on-board cameras, and the like for sensing the topographicalinformation. In one example, the electronic memory 122 may stores a mapor coordinate system representative of the physical environment in whichthe robot is present. Sensed topographical information may thentransmitted to the electronic control unit 120, which may determine arelative position of the system. Once the relative position isdetermined, the movement mechanism may guide the robot to the positionin which the image is projected in the identified projection area. Insome embodiments, the electronic memory 122 may include machine readableinstructions that, when executed by the processor 124, cause the robotto detect movement of the human (e.g., by analyzing image data acrossframes of image data), predict a future location of the human based onthe detected movement, and project the image on an area of a projectionsurface on which the human will be capable of viewing the image from thepredicted future location.

In some embodiments, the robot may receive data with the wirelesscommunicator 132. In such embodiments, the projected image may be basedon the received data. For example, in some embodiments, the projectedimage may be based on an image of a remote communicating party receivedvia the wireless communicator 132. In other embodiments, the receiveddata may include other information wirelessly transmitted by a remotecommunicating party and received by the wireless communicator 132. Instill other embodiments, the received data may include informationautomatically transmitted by a remote computing device and received bythe wireless communicator 132. In an embodiment including a speaker 134,the mechanical output of the speaker may be based on informationreceived wirelessly by the wireless communicator 132 (e.g., speech ofthe communicating party). However, it should be understood that anembodiment with a speaker 134 may communicate audible indications ofinformation other than information received by the wireless communicator132.

In some embodiments, machine readable instructions for determining adistance between the robot and the projection surface, determining asize of the projection surface, and scaling the projected image based onthe determined distance and the determined size, such that the entireprojected image is displayed on the projection surface are stored in theelectronic memory 122.

Referring now to FIGS. 5 and 2, a perspective view of a wheeled robot100 projecting an image 520 on a surface 500 viewable by a human 400 isschematically depicted. In order to project the image 520 on the surface500, the robot 100 has recognized the human 400 using the camera 160 asdescribed above, identified the projection surface 500 using the camera160 as described above, moved to a proper position, and projected theimage 520 on the identified projection surface 500 with the projector126 as described above.

Referring now to FIGS. 6 and 2, a perspective view of a flying robot 300projecting an image 520 on a surface 500 viewable by a human 400 isschematically depicted. In order to project the image 520 on the surface500, the flying robot 300 has recognized the human 400 using the camera160 as described above, identified the projection surface 500 using thecamera 160 as described above, moved to a proper position and projectedthe image 520 on the identified projection surface 500 with theprojector 126 as described above.

While the embodiments herein have been described in the context of asingle robot projecting an image on identified projection surface, itshould be understood that in other embodiments multiple robots maycooperate to project a single image on an identified projection surface.In some embodiments, a plurality of robots may each project a portion ofan image on the projection surface, such that the collective portionsform a single image. In one embodiment, a first robot, a second robot, athird robot, and a fourth robot may each project a quadrant of an imageon the identified projection surface. For example, the first robot mayproject the upper left quadrant of the image, the second robot mayproject the upper right quadrant of the image, the third robot mayproject the lower left quadrant of the image, and the fourth robot mayproject the lower right quadrant of the image. In some embodiments,multiple wheeled robots may each project a portion of an image on aprojection surface, such that the collective portions form a singleimage. In other embodiments, multiple flying robots may each project aportion of an image on a projection surface, such that the collectiveportions form a single image. In still other embodiments, a combinationof flying robots and wheeled robots may each project a portion of animage on a projection surface, such that the collective portions forma asingle image.

It should now be understood that the embodiments described herein relateto robots comprising projectors for projecting images on identifiedprojection surfaces. The embodiments provide a flexible and adaptiverobotic projection system capable of identifying an appropriateprojection surface for projecting an image to an identified human. Inembodiments that do not include the projection surface as a part of therobot, the system may be small, lightweight, power efficient, andinexpensive because a relatively small robot can project a large imageon a projection surface.

It is noted that the terms “substantially” and “about” may be utilizedherein to represent the inherent degree of uncertainty that may beattributed to any quantitative comparison, value, measurement, or otherrepresentation. These terms are also utilized herein to represent thedegree by which a quantitative representation may vary from a statedreference without resulting in a change in the basic function of thesubject matter at issue.

While particular embodiments have been illustrated and described herein,it should be understood that various other changes and modifications maybe made without departing from the spirit and scope of the claimedsubject matter. Moreover, although various aspects of the claimedsubject matter have been described herein, such aspects need not beutilized in combination. It is therefore intended that the appendedclaims cover all such changes and modifications that are within thescope of the claimed subject matter.

What is claimed is:
 1. A robot comprising: a housing; an electroniccontrol unit coupled to the housing, wherein the electronic control unitcomprises a non-transitory memory that stores a set of machine readableinstructions and a processor for executing the machine readableinstructions; a projector coupled to the housing and communicativelycoupled with the electronic control unit; a human recognition modulecoupled to the housing and communicatively coupled with the electroniccontrol unit; and a projection surface identification module coupled tothe housing and communicatively coupled with the electronic controlunit, wherein when executed by the processor, the machine readableinstructions cause the robot to: recognize a human using the humanrecognition module; identify a location of the human using the humanrecognition module; identify a projection area based on the identifiedlocation of the human using the projection surface recognition module;and project an image on the identified projection area with theprojector.
 2. The robot of claim 1 further comprising a movementmechanism coupled to the housing and communicatively coupled with theelectronic control unit, wherein when executed by the processor, themachine readable instructions further cause the robot to: cause themovement mechanism to move the robot to a position in which the image isprojected on the identified projection area.
 3. The robot of claim 2,wherein the movement mechanism comprises: a drive wheel rotatablycoupled to the housing; a drive motor coupled to the drive wheel andcommunicatively coupled with the electronic control unit; and a steeringmechanism coupled to the housing and communicatively coupled with theelectronic control unit.
 4. The robot of claim 2, wherein the movementmechanism comprises a rotor and a drive motor coupled to the rotor. 5.The robot of claim 1 further comprising a wireless communicator coupledto the housing and communicatively coupled with the electronic controlunit, wherein when executed by the processor, the machine readableinstructions further cause the robot to: receive data with the wirelesscommunicator; and generate the projected image based on the receiveddata.
 6. The robot of claim 1, wherein when executed by the processor,the machine readable instructions further cause the robot to: determinea distance between the robot and the projection area; determine a sizeof the projection area; and scale the projected image based on thedetermined distance and the determined size, such that the entireprojected image is displayed on the projection area.
 7. The robot ofclaim 1 further comprising a movement mechanism coupled to the housingand communicatively coupled with the electronic control unit, whereinwhen executed by the processor, the machine readable instructionsfurther cause the robot to: identify an orientation of the human usingthe human recognition module; identify the projection area based on theorientation of the human; and cause the movement mechanism to move therobot to a position in which the image is projected on the identifiedprojection area.
 8. The robot of claim 1, wherein the human recognitionmodule comprises a camera communicatively coupled to the electroniccontrol unit and the recognition of the human is based on facialrecognition of an image received from the camera.
 9. The robot of claim1, wherein the human recognition module comprises a microphonecommunicatively coupled to the electronic control unit and therecognition of the human is based on a mechanical vibration received bythe microphone and transformed into a signal indicative of human speechthat is transmitted to the electronic control unit.
 10. The robot ofclaim 1, wherein the projection surface identification module comprisesa camera communicatively coupled to the electronic control unit.
 11. Therobot of claim 1, wherein the projector is a pico projector.
 12. Therobot of claim 1, wherein the projected image substantially resembles ahuman.
 13. The robot of claim 1, wherein the projected image comprises aface.
 14. The robot of claim 1 further comprising a speaker forproviding an audible indication of the received information to thehuman, wherein the speaker is communicatively coupled to the electroniccontrol unit.
 15. A robot comprising: a housing; an electronic controlunit coupled to the housing, wherein the electronic control unitcomprises a non-transitory memory that stores a set of machine readableinstructions and a processor for executing the machine readableinstructions; a projector coupled to the housing and communicativelycoupled with the electronic control unit; and a camera coupled to thehousing and communicatively coupled with the electronic control unit,wherein when executed by the processor, the machine readableinstructions cause the robot to: recognize a human using the camera;identify a location of the human using the camera; identify a projectionarea based on the identified location of the human using the camera; andproject an image on the identified projection area with the projector.16. The robot of claim 15 further comprising: a drive wheel rotatablycoupled to the housing; a drive motor coupled to the drive wheel andcommunicatively coupled with the electronic control unit; and a steeringmechanism coupled to the housing and communicatively coupled with theelectronic control unit, wherein when executed by the processor, themachine readable instructions further cause the robot to: cause thedrive motor to rotate the drive wheel and the steering mechanism tosteer the robot to a position in which the image may be projected on theidentified projection area.
 17. The robot of claim 15 further comprisinga wireless communicator coupled to the housing and communicativelycoupled with the electronic control unit, wherein when executed by theprocessor, the machine readable instructions further cause the robot to:receive data with the wireless communicator; and generate the projectedimage based on the received data.
 18. A robot comprising: a housing; anelectronic control unit coupled to the housing, wherein the electroniccontrol unit comprises a non-transitory memory that stores a set ofmachine readable instructions and a processor for executing the machinereadable instructions; a projector coupled to the housing andcommunicatively coupled with the electronic control unit; a microphonecoupled to the housing and communicatively coupled with the electroniccontrol unit; and a camera coupled to the housing and communicativelycoupled with the electronic control unit, wherein when executed by theprocessor, the machine readable instructions cause the robot to:recognize a human based on a mechanical vibration received by themicrophone and transforming the mechanical vibration into a signalindicative of human speech that is transmitted to the electronic controlunit; identify a location of the human using the microphone; identify aprojection area based on the identified location of the human using thecamera; and project an image on the identified projection area with theprojector.
 19. The robot of claim 18 further comprising a wirelesscommunicator coupled to the housing and communicatively coupled with theelectronic control unit, wherein when executed by the processor, themachine readable instructions further cause the robot to: receive datawith the wireless communicator; and generate the projected image basedon the received data.
 20. The robot of claim 18 further comprising: adrive wheel rotatably coupled to the housing; a drive motor coupled tothe drive wheel and communicatively coupled with the electronic controlunit; and a steering mechanism coupled to the housing andcommunicatively coupled with the electronic control unit, wherein whenexecuted by the processor, the machine readable instructions furthercause the robot to: cause the drive motor to rotate the drive wheel andthe steering mechanism to steer the robot to a position in which theimage may be projected on the identified projection area.